WO2016120713A2 - Topical composition and method for preparing same - Google Patents

Abstract

The invention relates to a composition for topical application, in particular a cosmetic composition, containing plant cells dedifferentiated and elicited in in vitro culture, which are elicited in an in vitro medium in a gaseous atmosphere containing oxygen and CO2 at a temperature of 15 °C to 50 °C according to a cycle which includes periods of low luminosity separated from one another by periods of high luminosity.

Description

 Topical composition and method of preparation

This international patent application claims the priority of the European patent application 15 000 285.5 filed January 30, 2015 in the name of E NAMANY Rachid.

The invention relates to a composition for topical use, in particular cosmetic, rich in metabolites produced by plant cells from particular plants. In particular, the subject of the invention is a composition containing dedifferentiated and elicited plant cells and then partially or totally dried, preferably lyophilized, optionally (but advantageously) crushed and then dispersed in this composition.

By dedifferentiated plant cells is meant any plant cell having none of the characters of a particular specialization and capable of living on its own and not dependent on other cells.

Dedifferentiated plant cells can be obtained from plant material derived from whole plant or part of plant such as leaves, stems, flowers, petals, roots, fruits, their skin, the envelope protecting them, seeds, anther, sap, thorns, buds, bark, berries, and mixtures thereof.

Preferentially, dedifferentiated plant cells are obtained from bark, leaves, buds and fruit skin.

The dedifferentiated plant cells that can be used according to the invention can be obtained from plants obtained by in vivo culture or from culture in vitro. In vivo culture is understood to mean any culture of conventional type, ie in soil in the open air or in a greenhouse, or above ground or in a hydroponic medium. By in vitro culture is meant all the techniques known to those skilled in the art which artificially allows the production of a plant or part of a plant. The pressure of selection imposed by the physicochemical conditions during the growth of the plant cells in vitro makes it possible to obtain a standardized plant material, free from contaminations and available throughout the year unlike plants cultivated in vivo.

Preferably, according to the invention, dedifferentiated plant cells originating from in vitro culture are used.

The dedifferentiated plant cells that can be used according to the invention can be obtained by any method known from the prior art. In this regard, the methods described by E. F. George and P. D. Sherrington can be cited in Plant Propagation by Tissue Culture, Handbook and Directory of Commercial Laboratories (Exegetics Ltd 1984).

The culture media that can be used according to the invention are those generally known to those skilled in the art. Examples of such are Gamborg, Murashige and Skoog, Heller, White, etc ... Media can be found in EF George's Plant Culture Media: Formulations and Uses, DJM Puttock and HJ George (Exegetics Ltd 1987). , volumes 1 & 2) complete descriptions of these environments.

Preferably, the dedifferentiated plant cells cultivated on Murashige and Skoog medium are prepared according to the invention. State of the art

Document FR 2795637 discloses a cosmetic composition containing an extract of dedifferentiated plant cells to avoid odor problems. This composition contains an extract of dedifferentiated but unelected plant cells, so that this composition is poor in secondary metabolites or phytoalexins, or is substantially free of such compounds. In addition, this document describes the use of aqueous extract obtained after grinding the cells in their culture medium and then removing suspended particles with an inevitable loss of metabolites bound to suspended particles. In order to eliminate proteases and especially oxidases, this document also recommends the use of filters capturing molecules with a molecular weight greater than 100,000 daltons thus losing in the final extract all the metabolites greater than this weight and which can prove to be of great interest to the cosmetics industry. In addition, in order to eliminate the problems due to oxidation, the document recommends the addition of stabilizers, in particular cysteine and / or sulfur derivatives, which necessarily entails a lower purity of the extract with subsequent filtration steps. The methods described in this document require the implementation of complicated means for obtaining extracts whose purity (many additives), quality and concentration (metabolites) is not optimal. In addition, the many steps necessary to obtain the extracts of this process lead to high costs and the risk of contaminations due to the many manipulations and additives.

Dedifferentiated cell cultures are known, on the other hand the mechanisms of elicitation of these cells are known, followed by steps of extractions and various filtrations followed by lyophilization in order to incorporate the extracts obtained in a cosmetic or pharmaceutical preparation. Such methods are for example described in US 4,241,536; EP 378 921, WO 88/00968, EP 1 203 811, etc. for various plant species. The contents of these documents are incorporated herein by reference to describe culture media, plant species, possible elicitors, etc.

Today, despite the skills and know-how of industries in the field of plant extraction, and despite the progress of organic chemistry, several extraction steps are essential to obtain a plant raw material.

Several disadvantages are attributed to these extractions: - loss of the tertiary structure of the isolated molecules,

 - presence of different solvents in the finished product,

 heterogeneity of the substrates requiring fine extractions using increasingly toxic solvents,

- quality of the extract as a function of the physiological state of the plant at the time of harvest,

 - production of the limited extract according to the seasons,

Faced with these limiting factors and the renewed interest of consumers for all that is natural, several attempts to obtain cells have been made. Thus, to date, two major processes have been exploited:

- The culture of cells from unicellular organisms or microorganisms, a little original technique based on the reproduction of normal living conditions. However these organisms are primitive and do not develop secondary metabolism, source of the most interesting active ingredients.

 - Obtaining cells from fruits (fresh cells) after enzymatic digestion. The limits of this process lie in the fact that the fruits are not aseptic and that they can contain residues of pesticides (fungicides, herbicides, insecticides, ...). On the other hand, the enzymes (cellulases, pectinases, ...) used in significant quantity (2%, P / P) for the digestion of the plant walls and the obtaining of the cells without wall (protoplasts) are found in the product. finished. In addition, the enzymes used can alter the quality of the metabolites. Finally, the use of this technique only makes it possible to recover protoplasts (cells without a cell wall), fragile structures that can not orient their metabolism.

Also known from WO 03/077880 is a process for preparing a homogenized and dedifferentiated cell broth to produce phytoalexins. In this document, the plant cells are selected from particular families and are elicited according to particular steps. The inventors have now discovered that by subjecting dedifferentiated cells of particular plant plant families to a particular elicitation cycle, it was possible to obtain cells containing a mixture of molecules in relative proportions to each other which made it possible to ensure adequate treatment of skin problems.

The subject of the invention is a composition for topical application, in particular a cosmetic composition, containing dedifferentiated and elicited plant cells in in vitro culture, advantageously in the form of crushed indipententiated and dedifferentiated plant cells in in vitro culture, said mash containing at least a phytoalexine then comprising at least 95%, advantageously at least 97%, preferably at least 99% by weight of all the dry matter derived from the dedifferentiated and elicited plant cells in vitro, said cells or said ground being dispersed (es ) in said composition or being in a form capable of being dispersed in said composition, characterized in that the dedifferentiated plant cells, optionally (but advantageously) in the form of crushed material, are chosen from the group consisting of the following families: Agavaceae (in particular the species: Agave, Beschorneria, Cororophytum, Furcraea, Hesperaloe, Hesperoyucca, Yucca), Aizoaceae, Amaranthaceae (in particular the species: Arthraerva), Amaryllidaceae (in particular the species: Boophane, Brunsvigia, Cyrtanthus, Haemanthus, Rauhia), Anacardiaceae (in particular the species : Operculicarya, Pachycormus), Apiaceae (in particular the species: Steganotaenia), Apocynaceae (in particular the species: Adenium, Mandevilla, Pachypodium, Plumeria), Araceae (in particular the species: Zamioculcas zamiifolia); Araliaceae (in particular the species: Cussonia), Asclepiadaceae (in particular the species: Absolmsia, Asclepias, Aspidoglossum, Aspidonepsis, Baynesia, Brachystelma, Caralluma, Ceropegia, Cibirhiza, Cynanchum, Dischidia, Dischidiopsis, Duvalia, Duvaliandra, Echidnopsis, Edithcolea, Fanninia , Fockea, Glossostelma, Hoodia, Hoya, Huernia, Huerniopsis, Ischnolepis, Larryleachia, Lavrania, Madangia, Marsdenia, Matelea, Micholitzia, Miraglossum, Notechidnopsis, Odontostelma, Ophionella, Orbea, Orbeanthus, Pachycarpus, Pectinaria, Petopentia, Piaranthus, Pseudolithos, Quaqua, Raphionacme, Pvhytidocaulon, Riocreuxia, Sarcorrhiza, Sarcostemma, Schizoglossum, Schlechterella, Stapelia, Stapelianthus, Stapeliopsis, Stathmostelma, Stenostelma, Stomatostemma, Tavaresia, Trachycalymma, Tridentea, Tromotriche, White- sloanea, Xysmalobium), Asparagaceae (in particular species: Myrsiphyllum), Asphodelaceae ((in particular species: Aloe, Astroloba, Bulbine, Chortolirion, Gasteria, Haworthia, Poellnitzia, Trachyandra), Asteraceae ( in particular the species: Baeriopsis, Coulterella, Crassocephalum, Didelta, Gynura, Osteospermum, Othonna, Polyachyrus, Pteronia, Senecio), Balsarninaceae (in particular the species: Impatiens), Basellaceae (in particular the species: Anredera, Basella), Begoniaceae ( in particular the species: Begonia), Bombacaceae (in particular the species: Adansonia, Cavanillesia, Ceiba, Pseudobombax) , Brassicaceae (in particular the species: Heliophila, Lepidium), Bromeliaceae, Burseraceae (in particular the species: Beiselia, Bursea, Comrniphora), Cactaceae (in particular the species: Acanthocalycium, Acanthocereus, Ariocarpus, Armatocereus, Arrojadoa, Arthrocereus, Astrophytum, Austrocactus, Aztekium, Bergerocactus, Blossfeldia, Brachycereus, Browningia, Brasilicereus, Calymmanthium, Carnegiea, Cephalocereus, Cephalocleistocactus, Cereus, Cintia, Cipocereus, Cleistocactus, Coleocephalocereus, Copiapoa, Corryocactus, Coryphantha, Denrocereus, Denmoza, Discocactus, Disocactus, Echinocactus, Echinocereus, Echinopsis, Epiphyllum, Epithelantha, Eriosyce, Escobaria, Escontria, Espostoa, Espostoopsis, Eulychnia, Facheiroa, Ferocactus, Frailea, Geohintonia, Gymnocalycium, Haageocereus, Harrisia, Hatiora, Hylocereus, Jasmineocereus, Lasiocereus, Leocereus, Lepismium, Leptocereus, Leuchtenbergia, Lophophora, Maihuenia, Malacocarpus, Mammillaria, Mammilloydia, Matucana, Melocactus, Micranthocereus, Mila, Monvillea, Myrtillocactus, Neobuxbaumia, Neolloydia, Neoraimondia, Neowerdermannia, Obregonia, Opuntia, Oreocereus, Oroya, Ortegocactus, Pachycereus, Parodia, Pediocactus, Pelomyphora, Peniocereus, Pereskia, Pereskiopsis, Pilosocereus, Polaskia, Praecereus, Pseudoacanthocereus, Pseudorhipsalis, Pterocactus, Pygmaeocereus, Quiabentia, Rauhocereus, Rebutia, Rhipsalis, Samaipaticereus, Schlumbergera, Sclerocactus, Selenicereus, Stenocactus, Stenocereus, Stephnocereus, Stetsonia, Strombocactus, Tacinga, Thelocactus, Turbinicarpus, Uebelmannia, Weberbauerocereus, Weberocereus, Yungasocereus), Campanulaceae (in particular species: Brighamia), Capparidaceae (in particular species: Maerua) , Caricaceae (in particular the species: Carica, Jacarathia), Chenopodiaceae, Cochlospermaceae, Cornmelinaceae (in particular the species: Aneilema, Callisia, Cyanotis, Tradescantia, Tripogandra), Convolvulaceae (in particular the species: Ipomea, Sictocardia, Turbina), Crassulaceae (in particular the species: Adromischus, Aeonium, Afrovivella, Aichryson, Cotyledon, Crassula, Cremnophila, Cremnosedum, Dudleya, Echeveria, Graptopetalum, Hylotelephium, Hypagophytum, Kalanchoe, Lenophyllum, Meterostachys, Monanthes, Orostachys, Pachyphytum, Perrierosedum, Phedimus, Pistorinia, Prometheum, Pseudosedum, Rhodiola, Rosulana, Sedella, Sedum, Sempervivum, Sinocrassula, Thompsonella, Tylecodon, Umbilicus, Villadia), Cucurbitaceae (in particular the species: Apodanthera, Brandegea, Cephalopentandra, Ceratosanthes, Citrullus, Coccinia, Corallocarpus, Cucumella, Cucumis, Cucurbita, Cyclantheropsis, Dendrosicyos, Doyera, Eureindra, Fevillea, Gerrandanthus, Gynostemma, Halosicyos, Ibervilla, Kedostris, Marah, Momordica, Neoalsomitra, Odosicyos, Parasicyos, Syrigia, Telfairia, Trochomeria, Trochomeriopsis, Tumamoca, Xerosicyos, Zehneria, Zygosicyos), Didiereaceae (especially the species: Alluaudia, Alluaudiopsis, Decaria, Didieara), Dioscoreaceae (in particular the species: Dioscorea), Doryanthaceae (in particular the species: Doryanthes), Ericaceae (in particular the species: Sphyrospermum), Eriospermaceae "(in particular the species: Eriospermum), Euphorbiaceae, Fabaceae (in particular the species: Delonix , Dolichos, Eiythrina, Neorautanenia, Pachyrhizus, Tylosema), Fouquieriaceae (in particular the species: Fouquieria), Geraniaceae (in particular the species: Monsonia, Pelargonium), Gesneriaceae (in particular the species: Aeschynanthus, Alsobia, Chirita, Codonanthe, Columnea, Nematanthus, Siriningia, Streptocarpus), Hyacinthaceae (in particular the species: Albuca, Bowiea, Dipcadi, Drimia, Drimiopsis, Hyacinthus, Lachenalia, Ledebouria, Litanthus, Massonia, Ornithogalum, Rhadamanthus, Rhodocodon, Schizobasis, Whiteheadia), Icacinaceae (in particular the species: Pyrenacantha), Lamiaceae (in particular the species: Aeollanthus, Dauphinea, Perrierastrum, Plectranthus, Solenostemon, Tetradenia, Thorncroftia), Lentibulariaceae, Loasaceae (in particular species: Schismocarpus), Loranthaceae (in particular species : Tapinanthus), Melastomataceae (in particular species: Medinilla), Meliaceae (in particular species: Entandrophragma), Menispermaceae (in particular species: Chasmanthera, Stephania, Tinospora), Moraceae (in particular species: Dorstenia, Ficus), Moringaceae (in particular species: Moringa), Nolanaceae (in particular species: Nolana), Nolinaceae (in particular species: Beaucarnea, Calibanus, Dasylirion, Nolina), Orchidaceae, Oxalidaceae (in particular species: Oxalis), Passifloraceae ( in particular the species: Adenia), Pedaliaceae (in particular the species: Pterodiscus, Sesamothamnus, Uncarina), Phyllanthaceae (in particular the species: Phyllanthus), Phytolaccaceae (in particular species: Phytolacca), Piperaceae (in particular species: Peperomia),. Portulacaceae (in particular the species: Amphipetalum, Anacampseros, Avonia, Calyptrotheca, Ceraria, Cistanthe, Dendroportulaca, Grahamia, Lewisia, Parakeel, Portulaca, Portulacaria, Schreiteria, Talinella, Talinum), Rubiaceae (in particular the species: Anthorrhiza, Hydnophytum, Hydrophylax , Myrmecodia, Myrmephythum, Phylohydrax, Squamellaria), Ruscaceae (in particular species: Cordyline, Dracaena, Sansevieria), Sapindaceae (in particular species: Erythrophysa), Saxifragaceae, Sterculiaceae (in particular species: Brachychiton, Sterculia), Urticaceae ( in particular the species: Laportea, Obertia, Pilea, Sarcopilea), Viscaceae (in particular the species: Viscum), Vitaceae (in particular the species: Cissus, Cyphostemma), Xanthorrhoeaceae and Zygophyllaceae, which have been elicited in vitro in a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C and 50 ° C in a cycle with low light periods inosity with a brightness of less than 10 lux (in particular from 1 to 5 lux) for 10 minutes to 12 hours, advantageously for 15 minutes and 0 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from one of the other by a period of brightness of more than 100 lux for 30 minutes to 24 hours, preferably 1 hour to 12 hours, of preferably from 1 to 6 hours (in particular more than 1000 lux, more specifically more than 10000 lux, preferably more than 50000 lux and even more preferably more than 100000 lux), optionally followed by a grinding step for to form a crushed de dedifferentiated plant cells. Said dedifferentiated and elicited plant cells, optionally before being crushed, are subjected to a step of separating the culture medium and / or washing and / or rinsing and / or drying. The gaseous atmosphere for the culture and elicitation of the cells advantageously comprises less than 20% by volume of oxygen, for example 10 to 19% by volume, more than 0.5% by volume of CO 2, preferably 1 at 5% by volume of CO2, water to obtain a relative humidity of more than 25%, advantageously of more than 50%, for example close to saturation, nitrogen. According to a particular method, the atmosphere is air enriched in CO 2 and moisture if necessary. In the present specification, the term "brightness" means illumination with wavelength rays between 100 nm and 700 nm, in particular in the visible spectrum, and preferably in the range of 400 nm to 520 nm (corresponding to the spectrum In the lighting steps, the illumination advantageously comprises substantially no rays of wavelength less than 100 nm and / or greater than 700 nm, preferably more than 90% of the rays, in particular more than 95% of the rays have a wavelength of between 100 nm and 700 nm, preferably between 400 nm and 520 nm.

In this specification, the periods of non-luminosity are advantageously periods in which the culture medium is substantially not subjected to radiation of wavelength between 100 nm and 700 nm, but also preferably less than 100 nm and greater than 100 nm. 700nm. The periods of non-luminosity are preferably periods of total or substantially total darkness.

According to an advantageous embodiment of the composition according to the invention, the plant cells have been eluted in vitro in a gaseous atmosphere containing oxygen and CO 2 at a temperature between 15 ° C and 50 ° C in a cycle comprising at least four, in particular at least six, preferably at least ten periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness of more than 100 lux for 30 minutes to 24 hours preferably 1 hour to 12 hours, preferably 1 to 6 hours. Said dedifferentiated and elicited plant cells are subjected to a separation step of the culture medium and / or washing and / or rinsing and / or drying. Said cells, advantageously after separation from the culture medium and / or washing and / or drying, are preferably milled before or after mixing with a cosmetically acceptable compound.

 According to a feature of a composition according to the invention, the plant cells have been eluted in vitro in an atmosphere containing a degree of humidity of more than 50%.

 In the compositions according to the invention, the cells have been advantageously prepared using one or more of the following characteristics:

 the plant cells are dedifferentiated and elicited in an in vitro culture medium under a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C. and 50 ° C. in a cycle comprising periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness of more than 100 lux during 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours (in particular more than 1000 liters, more specifically more than 50000 and even more than 100000 lux), before being crushed.

the change in brightness during the transition from a period of brightness less than 10 lux to a period of brightness of more than 1000 lux (advantageously more than 500 000 lux) takes place in a time of less than 5 minutes, in particular of less than 2 minutes. the plant cells are at least partially elicited by periods of brightness of more than 50000 lux, in particular of more than 100 000 lux, for example of more than 150000 lux.

 the plant cells are dedifferentiated and elicited in an in vitro medium under an oxygen-containing atmosphere (in particular less than 21% by volume, more specifically less than 20% by volume, for example from 10 to 18% by volume) and minus 1% (especially 2 to 10%) of C02 by volume.

 the plant cells are dedifferentiated and elicited in an in vitro medium under a gaseous atmosphere containing oxygen and at least 1% by volume of CO2, and a relative humidity of at least 50% according to a cycle comprising periods of low light with a luminosity of less than 10 lux (for example from 2 to 51ux) at a temperature between 15 ° C. and 30 ° C. for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a brightness period of more than 1000 lux for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours (preferably more than 10000 lux, preferably more than 50000 lux) at a temperature of more than 30 ° C. The cells are advantageously subjected to a separation of the cells from the culture medium, their washing and / or drying and / or rinsing, and optionally followed, but advantageously to a grinding, optionally after mixing the cells with a compound or excipient for a cosmetic product ( for example oil, glycol, etc.).

According to advantageous features of embodiments, the composition according to the invention comprises one or more of the following characteristics:

the cells are in the form of a pulp of dedifferentiated and elicited cells in vitro, said cells being at least partially dried, preferably lyophilized, before being milled.

 the composition contains from 0.005 to 25% by weight, advantageously from 0.005 to 5% by weight of dedifferentiated and elicited plant cells in vitro, in particular in the form of ground matter, this weight being calculated in dry form.

- The ground has a mean particle size of solid particles less than 100 μηι, preferably less than 10 μπι, preferably less than 1 μηι. the undifferentiated and elicited non-crushed in vitro plant cells or the dedifferentiated and elicited plant cell broth in vitro is in the form of a viscous suspension or a substantially dry gel or powder, said suspension being gel or powder being advantageously in a form capable of being dispersed in the composition.

 the composition is an antioxidant, anti-radical, anti-inflammatory, anti-proliferative, relaxant, vascular and / or anti-aging composition, said composition comprising an effective amount of plant cells as described above and / or plant cell broths as described above.

The subject of the invention is also a process for the preparation of a composition for topical use according to the invention, this process being essentially characterized in that dedifferentiated plant cells of a species chosen from the group consisting of of the following families: Agavaceae (in particular the species: Agave, Beschorneria, Chlorophytum, Furcraea, Hesperaloe, Hesperoyucca, Yucca), Aizoaceae, Amaranthaceae (in particular the species: Arthraerva), Amaryllidaceae (in particular the species: Boophane, Brunsvigia , Cyrtanthus, Haemanthus, Rauhia), Anacardiaceae (in particular the species: Operculicarya, Pachycormus), Apiaceae (in particular the species: Steganotaenia), Apocynaceae (in particular the species: Adenium, Mandevilla, Pachypodium, Plumeria), Araceae (in particular the species: Zamioculcas zamiifolia); Araliaceae (in particular the species: Cussonia), Asclepiadaceae (in particular the species: Absolmsia, Asclepias, Aspidoglossum, Aspidonepsis, Baynesia, Brachystehna, Caralluma, Ceropegia, Cibirhiza, Cynanchum, Dischidia, Dischidiopsis, Duvalia, Duvaliandra, Echidnopsis, Edithcolea, Fanninia , Fockea, Glossostelma, Hoodia, Hoya, Huernia, Huerniopsis, Ischnolepis, Larryleachia, Lavrania, Madangia, Marsdenia, Matelea, Micholitzia, Miraglossum, Notechidnopsis, Odontostelma, Ophionella, Orbea, Orbeanthus, Pachycarpus, Pectinaria, Petopentia, Piaranthus, Pseudolithos, Quaqua , Raphionacme, Rhytidocaulon, Riocreuxia, Sarcorrhiza, Sarcostemma, Schizoglossum, Schlechterella, Stapelia, Stapelianthus, Stapeliopsis, Stathmostelma, Stenostelma, Stomatostemma, Tavaresia, Trachycalymma, Tridentea, Tromotriche, White-sloanea, Xysmalobium), Asparagaceae particular species: Myrsiphyllum), Asphodelaceae ((in particular the species: Aloe, Astroloba, Bulbine, Chortolirion, Gasteria, Haworthia, Pellnitzia, Trachyandra), Asteraceae (in particular the species: Baeriopsis, Coulterella, Crassocephalum, Didelta, Gynura, Osteospermum , Othonna, Polyachyrus, Pteronia, Senecio), Balsaminaceae (in particular the species: Impatiens), Basellaceae (in particular the species: Anredera, Basella), Begoniaceae (in particular the species: Begonia), Bombacaceae (in particular the species: Adansonia , Cavanillesia, Ceiba, Pseudobombax), Brassicaceae (in particular the species: Heliophila, Lepidium), Bromeliaceae, Burseraceae (in particular the species: Beiselia, Bursea, Commiphora), Cactaceae (in particular the species: Acanthocalycium, Acanthocereus, Ariocarpus, Armatocereus , Arrojadoa, Arthrocereus, Astrophytum, Austrocactus, Aztekium, Bergerocactus, Blossfeldia, Brachycereus, Browningia, Brasilicereus, Calymmanthium, Carnegiea , Cephalocereus, Cephalocleistocactus, Cereus, Cintia, Cipocereus, Cleistocactus, Coleocephalocereus, Copiapoa, Corryocactus, Coryphantha, Dendrocereus, Denmoza, Discocactus, Disocactus, Echinocactus, Echinocereus, Echinopsis, Epiphyllum, Epithelantha, Eriosyce, Escobaria, Escontria, Espostoa, Espostoopsis, Eulychnia , Facheiroa, Ferocactus, Frailea, Geohintonia, Gymnocalycium, Haageocereus, Harrisia, Hatiora, Hylocereus, Jasminocereus, Lasiocereus, Leocereus, Lepismium, Leptocereus, Leuchtenbergia, Lophophora, Maihuenia, Malacocarpus, Mamrnillaria, Mammilloydia, Matucana, Melocactus, Micranthocereus, Mila, Monvillea , Myrtillocactus, Neobuxbaumia, Neolloydia, Neoraimondia, Neowerdermannia, Obregonia, Opuntia, Oreocereus, Oroya, Ortegocactus, Pachycereus, Parodia, Pediocactus, Pelomyphora, Peniocereus, Pereskia, Pereskiopsis, Pilosocereus, Polaskia, Praecereus, Pseudoacanthocereus, Pseudorhipsalis, Pterocactus, Pygmaeocereus, Quiabentia , Rauhocereus, Rebutia, Rhipsalis, Samaipaticereus, Schlumbergera, Sclerocactus, Selenicereus, Stenocactus, Stenocereus, Stephanocereus, Stetsonia, Strombocactus, Tacinga, Thelocactus, Turbinicarpus, Uebelmannia, Weberbauerocereus, Weberocereus, Yungasocereus), Campanulaceae (in particular species: Brighamia), Capparidaceae (especially species: Maerua) , Caricaceae (in particular the species: Carica, Jacarathia), Chenopodiaceae, Cochlospermaceae, Cornmelinaceae (in particular the species: Aneilema, Callisia, Cyanotis, Tradescantia, Tripogandra), Convolvulaceae (in particular the species: Ipomea, Sictocardia, Turbina), Crassulaceae (in particular the species: Adromischus, Aeonium, Afrovivella, Aichryson, Cotyledon, Crassula , Cremnophila, Crernnosedum, Dudleya, Echeveria, Graptopetalum, Hylotelephium, Hypagophytum, Kalanchoe, Lenophyllum, Meterostachys, Monanthes, Orostachys, Pachyphytum, Perrierosedum, Phedimus, Pistorinia, Prometheum, Pseudosedum, Rhodiola, Rosularia, Sedella, Sedum, Sempervivum, Sinocrassula, Thompsonella , Tylecodon, Umbilicus, Villadia), Cucurbitaceae (in particular the species: Apodanthera, Brandegea, Cephalopentandra, Ceratosanthes, Citrullus, Coccinia, Corallocarpus, Cucumella, Cucumis, Cucurbita, Cyclantheropsis, Dendrosicyos, Doyera, Eureindra, Fevillea, Gerrandanthus, Gynostemma, Halosicyos , Ibervilla, Kedostris, Marah, Momordica, Neoalsomitra, Odosicyos, Parasicyos, Syrigia, Telfairia, Trocho meria, Trochomeriopsis, Tumamoca, Xerosicyos, Zehneria, Zygosicyos), Didiereaceae (in particular the species: Alluaudia, Alluaudiopsis, Decaria, Didieara), Dioscoreaceae (in particular the species: Dioscorea), Doryanthaceae (in particular the species: Doryanthes), Ericaceae (in particular the species: Sphyrospermum), Eriospermaceae (in particular the species: Eriospermum), Euphorbiaceae, Fabaceae (in particular the species: Delonix, Dolichos, Erythrina, Neorautanenia, Pachyrhizus, Tylosema), Fouquieriaceae (in particular the species: Fouquieria) , Geraniaceae (in particular the species: Monsonia, Pelargonium), Gesneriaceae (in particular the species: Aeschynanthus, Alsobia, Chirita, Codonanthe, Columnea, Nematanthus, Siriningia, Streptocarpus), Hyacinthaceae (in particular the species: Albuca, Bowiea, Dipcadi, Drimia, Drimiopsis, Hyacinthus, Lachenalia, Ledebouria, Litanthus, Massonia, Ornithogalum, Rhadamanthus, Rhodocodon, Schizobasis, Whiteheadia), Icacinaceae ( in particular the species: Pyrenacantha), Lamiaceae (in particular the species: Aeollanthus, Dauphinea, Perrierastrum, Plectranthus, Solenostemon, Tetradenia, Thorncroftia), Lentibulariaceae,. Loasaceae (in particular species: Schismocarpus), Loranthaceae (in particular species: Tapinanthus), Melastomataceae (in particular species: Medmilla), Meliaceae (in particular species: Entandrophragma), Menispermaceae (in particular species: Chasmanthera, Stephania, Tinospora), Moraceae (in particular the species: Dorstenia, Ficus), Moringaceae (in particular the species: Moringa), Nolanaceae (in particular the species: Nolana), Nolinaceae (in particular the species: Beaucarnea, Calibanus, Dasylirion, Nolina), Orchidaceae, Oxalidaceae (in particular species: Oxalis), Passifloraceae (in particular species: Adenia), Pedaliaceae (in particular species: Pterodiscus, Sesamothamnus, Uncarina), Phyllanthaceae (in particular species: Phyllanthus) , Phytolaccaceae (in particular the species: Phytolacca), Piperaceae (in particular the species: Peperomia), Portulacaceae (in particular the species: Amphipetalum, Anacampseros, Avonia, Calyptrotheca, Ceraria, Cistanthe, Dendroportulaca, Grahamia, Lewisia, Parakeelya, Portulaca, Portulacaria, Schreiteria, Talinella, Talinum), Rubiaceae (in particular the species: Anthorrhiza, Hydnophytum, Hydrophylax, Myrmecodia, Myrmephythum, Phylohydrate, Squamellaria), Rusc aceae (in particular species: Cordyline, Dracaena, Sansevieria), Sapindaceae (in particular species: Erythrophysa), Saxifragaceae, Sterculiaceae (in particular species: Brachychiton, Sterculia), Urticaceae (in particular species: Laportea, Obertia, Pilea , Sarcopilea), Viscaceae (in particular the species: Viscum), Vitaceae (in particular the species: Cissus, Cyphostemma), Xanthorrhoeaceae and Zygophyllaceae, in an in vitro culture medium so as to allow growth of the cells, while eliciting them said growth and elicitation being carried out in vitro in a gaseous atmosphere containing oxygen and CO 2 at a temperature between 15 ° C and 50 ° C according to a cycle comprising periods of low light with a brightness of less than 10 lux (in particular 1 to 5 lux) for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of time. with a brightness period of more than 100 lux for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours (in particular more than 1000 lux, more specifically more than 10,000 lux, preferably more than 50,000 lux and even more preferably more than 100,000 lux), in that said differentiated plant cells are cultured and elicited in their in vitro culture medium for a sufficient cycle. long in time for synthesis a sufficient quantity of metabolites in the dedifferentiated cells, in that, optionally, but advantageously, the cells are at least partially separated from the culture medium, and in that the elite plant cells of the culture medium are mixed with one or more several acceptable excipients for topical application to prepare a topical composition, advantageously cosmetic, according to the invention. The elite plant cells are optionally, but advantageously ground, for example before and / or after mixing them with one or more excipients (for example glycerol, glycol (s), oil (s)), but preferably at least after mixing them with acceptable excipient (s) (for example glycerin, glycol (s), oil (s)) for cosmetic application (topical).

In the process according to the invention, the gaseous atmosphere for the culture and the elicitation of the cells advantageously comprises less than 20% by volume of oxygen, for example from 10 to 19% by volume, more than 0.5% by volume. volume of CO2, preferably 1 to 5% by volume of CO2, water to obtain a relative humidity of more than 25%, preferably more than 50%, for example close to saturation, nitrogen. According to a particular method, the atmosphere is air enriched in CO 2 and moisture if necessary. According to an advantageous embodiment of the process according to the invention, the plant cells have been eluted in vitro in a gas atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C. and 50 ° C. in a cycle. comprising at least four, in particular at least six, preferably at least ten, low light periods with a brightness of less than 10 lux for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness of more than 100 lux for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours, before optionally being ground.

According to a feature of a process according to the invention, the plant cells have been eluted in vitro in an atmosphere containing a degree of humidity of more than 50%. In advantageous embodiments of the method according to the invention, the cells have been advantageously prepared using one or more of the following characteristics:

 the plant cells are dedifferentiated and elicited in an in vitro culture medium under a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C. and 50 ° C. in a cycle comprising periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness of more than 100 lux during 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours (in particular more than 1000 liters, more specifically more than 50000 and even more than 100000 lux), before possibly being crushed.

 - the change of brightness during the transition from a period of brightness below the lOux to a period of brightness of more than 100Oux

(advantageously more than 500001ux) is done in a time of less than 5 minutes, in particular less than 2 minutes.

 the plant cells are at least partially elicited by periods of brightness of more than 50000 lux, in particular of more than 100 000 lux, for example of more than 150000 lux.

 the plant cells are dedifferentiated and elicited in an in vitro medium under an oxygen-containing atmosphere (in particular less than 21% by volume, more specifically less than 20% by volume, for example from 10 to 18% by volume) and minus 1% (especially 2 to 10%) of C02 by volume.

the plant cells are dedifferentiated and elicited in an in vitro medium under a gaseous atmosphere containing oxygen and at least 1% by volume of CO2, and a relative humidity of at least 50% according to a cycle comprising periods of low light with a luminosity of less than 10 lux (for example from 2 to 51ux) at a temperature of between 15 ° C. and 30 ° C. for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours; darkness separated from each other by a brightness period of more than 1000 lux for 30 minutes to 24 hours, advantageously 1 hour to 12 hours. hours, preferably from 1 to 6 hours (advantageously from more than 100OOlux, preferably from more than 50000 lux) at a temperature of more than 30.degree. C., said cells then being optionally, but advantageously, subjected to a separation of the cells of the culture medium, and / or a washing step and / or a drying step and / or a rinsing step and / or a mixing step with one or more excipients. The cells are advantageously subjected to a grinding step, advantageously after a step of washing and / or drying of the cells and / or a step of mixing the cells with one or more excipients for cosmetic application.

the cells are first cultured to obtain dedifferentiated cells, the dedifferentiated cells thus obtained are placed in in vitro culture medium for their development under elicitation.

In the process according to the invention, one or more of the following steps are advantageously carried out:

said eluted cells are subjected in vitro to drying, advantageously to lyophilization, followed by grinding, before mixing the crushed cell with one or more acceptable excipients for topical application.

 dedifferentiated plant cells are cultured in vitro, elicited in the in vitro culture medium, dried and then ground, optionally after one or more washing and / or rinsing and / or drying steps, and dispersed in a treatment composition of the human body.

 the plant cells have been eluted in an in vitro medium under a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C. and 50 ° C. in a cycle comprising at least four, in particular at least six, of preferably at least ten periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, preferably for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness of more than 100 lux for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours, before optionally being crushed.

the plant cells have been eluted in vitro in an atmosphere containing a degree of relative humidity of more than 50%. the plant cells are dedifferentiated and elicited in an in vitro culture medium under a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C. and 50 ° C. in a cycle comprising periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, advantageously for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness of more than 100 lux during 30 minutes to 24 hours, advantageously 1 hour to 12 hours, preferably 1 to 6 hours, in particular more than 1000 minutes, before possibly being ground.

the plant cells are at least partially elicited by periods of brightness of more than 50000 lux, in particular of more than 100 000 lux.

 the plant cells are dedifferentiated and elicited in an in vitro medium under an atmosphere containing oxygen and at least 1% of CO2 by volume.

 the plant cells are dedifferentiated and elicited in an in vitro medium under a gaseous atmosphere containing oxygen and at least 1% by volume of CO2, and a relative humidity of at least 50% according to a cycle comprising periods of low light with a brightness of less than 10 lux at a temperature of between 15 ° C and 30 ° C for 10 minutes to 12 hours, preferably for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness separated; from one another by a period of brightness of more than 1000 lux for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours (preferably more than 10000 lux, preferably more than 50000 lux) ) at a temperature of more than 30 ° C, before being crushed.

 - The grinding of the cells is operated to obtain a crushed cell with an average particle size of solid particles less than 100 μηι, preferably less than 10 μπι, preferably less than 1 μπι.

The advantage of this process is that it makes it possible to obtain plant cells rich in particular molecules (from the family of stilbenes, flavanoids, neobetanine, alkaloids, vitamins, quercetin-3-methyl ether, fatty acids, rutin derivatives or rutinoside , galic acid, isorhamnetin, etc.) in adequate proportions in high volumes while meeting the needs of the industry, including: - Respect for the tertiary structure of molecules,

 - the absence of solvent and residues,

 - The homogeneity of the substrates,

 - Production continues regardless of the cycle of the seasons,

- The conservation of biological and physiological characteristics without the addition of preservatives,

 - the total absence of pollutants,

 - Standardized and reproducible production for the quality and concentration of metabolites,

- The use of these plant suspensions after direct lyophilization with use of temperature below -30 ° C. This technique makes it possible to obtain a very fine powder that can be dispersed in cosmetic compositions (creams, ointments, lotions, etc.). These cells are able to directly release the active ingredients they contain, without passing through an extraction using organic solvents (eliminating the risk of residues).

- The use of cell extracts only after sonification and centrifugation.

the use of the dedifferentiated and elite fresh plant cells, unmilled, mixed with a cosmetic excipient (for example glycerol, glycol (s), oil (s)). The fresh cells are avanatgeusement isolated from the culture medium, washed and optionally rinsed, before being optionally dried, before being mixed with one or more excipients for cosmetic application.

This technology provides a useful and innovative alternative to conventional solvent extraction. The possibility of natural orientation (elicitation) synthesis of metabolites without compromising the genetic integrity of cells, represents a guarantee of quality and authenticity. Surprisingly, the inventors have discovered that the cells can be directly incorporated or dispersed after elicitation, drying and grinding in a cosmetic and / or pharmaceutical composition. The composition according to the invention then contains cell membrane material. This method has the particular advantage of deactivating oxidizing enzymes without adding additives or chemicals. Another aspect of the invention makes it possible to concentrate and direct the production of phytoalexins without any quantitative or qualitative losses due to extractions and filtering. A particular aspect of the invention is that it avoids the extraction and filtering steps and makes it possible to obtain a grind of cells devoid of additives, solvents and residues, said grinds being able to be directly dispersed in a cosmetic composition.

By composition for topical use is meant creams, ointments, lotions, suspensions, sticks, shampoos, gels, serums, milks, lotions, creams, solutions (for example applicable by spray). The composition for topical use is for example a cosmetic, dermatological composition, a skin hygiene composition, a perfume, etc. Preferably according to the invention, the composition is a cosmetic composition.

The following examples and compositions illustrate the invention without limiting it in any way. In the compositions the. indicated proportions are percentages by weight.

 In these examples, a preferred method as defined in the following is used.

Process for obtaining a ground material

Step 1: Preparation of dedifferentiated and cultured cells in an in vitro culture medium This step of preparing dedifferentiated cells has been carried out in a conventional manner. For this step, plant cells from plants belonging to the following families were used:

Agavaceae (in particular the species: Agave, Beschorneria, Chlorophytum, Furcraea, Hesperaloe, Hesperoyucca, Yucca), Aizoaceae, Amaranthaceae (in particular the species: Arthraerva), Amaryllidaceae (in particular the species: Boophane, Brunsvigia, Cyrtanthus, Haemanthus , Rauhia), Anacardiaceae (in particular the species: Operculicarya, Pachycormus), Apiaceae (in particular the species: Steganotaenia), Apocynaceae (in particular the species: Adenium, Mandevilla, Pachypodium, Plumeria), Araceae (in particular species: Zamioculcas zamiifolia); Araliaceae (in particular the species: Cussonia), Asclepiadaceae (in particular the species: Absolmsia, Asclepias, Aspidoglossum, Aspidonepsis, Baynesia, Brachystelma, Caralluma, Ceropegia, Cibirhiza, Cynanchum, Dischidia, Dischidiopsis, Duvalia, Duvaliandra, Echidnopsis, Edithcolea, Fanninia , Fockea, Glossostelma, Hoodia, Hoya, Huernia, Huerniopsis, Ischnolepis, Larryleachia, Lavrania, Madangia, Marsdenia, Matelea, Micholitzia, Miraglossum, Notechidnopsis, Odontostelma, Ophionella, Orbea, Orbeanthus, Pachycarpus, Pectinaria, Petopentia, Piaranthus, Pseudolithos, Quaqua , Raphionacme, Rhytidocaulon, Riocreuxia, - Sarcorrhiza, Sarcostemma, Schizoglossum, Schlechterella, Stapelia, Stapelianthus, Stapeliopsis, Stathmostelma, Stenostelma, Stomatostemma, Tavaresia, Trachycalymma, Tridentea, Tromotriche, White-sloanea, Xysmalobium), Asparagaceae (in particular species: Myrsiphyllum), Asphodelaceae ((in particular the species: Aloe, Astroloba, Bulbine, Chortolirion, Gasteria, Hawor thia, Poellnitzia, Trachyandra), Asteraceae (in particular the species: Baeriopsis, Coulterella, Crassocephalum, Didelta, Gynura, Osteospermum, Othonna, Polyachyrus, Pteronia, Senecio), Balsaminaceae (in particular the species: Impatiens), Basellaceae (especially species: Anredera, Basella), Begoniaceae (in particular the species: Begonia), Bombacaceae (in particular the species: Adansonia, Cavanillesia, Ceiba, Pseudobombax), Brassicaceae (in particular the species: Heliophila, Lepidium), Bromeliaceae, Burseraceae (in particular particular species: Beiselia, Bursea, Commiphora), Cactaceae (in particular the species: Acanthocalycium, Acanthocereus, Ariocarpus, Armatocereus, Arrojadoa, Arthrocereus, Astrophytum, Austrocactus, Aztekium, Bergerocactus, Blossfeldia, Brachycereus, Browningia, Brasilicereus, Calymmanthium, Carnegiea, Cephalocereus, Cephalocleistocactus, Cereus, Cintia, Cipocereus, Cleistocactus, Coleocephalocereus, Copiapoa, Corryocactus, Coryphantha, Dendrocereus, Denmoza, Discocactus, Disocactus, Echinocactus, Echinocereus, Echinopsis, Epiphyllum, Epithelantha, Eriosyce, Escobaria, Escontria, Espostoa, Espostoopsis, Eulychnia, Facheiroa, Ferocactus, Frailea, Geohintonia, Gymnocalycium, Haageocereus, Harrisia, Hatiora, Hylocereus, Jasminocereus, Lasiocereus, Leocereus, Lepismium, Leptocereus, Leuchtenbergia, Lophophora, Maihuenia, Malacocarpus, Mammillaria, Mammilloydia, Matucana, Melocactus, Micranthocereus, Mila, Monvillea, Myrtillocactus, Neobuxbaumia, Neolloydia, Neoraimondia, Neowerdermannia, Obregonia , Opuntia, Oreocereus, Oroya, Ortegocactus, Pachycereus, Parodia, Pediocactus, Pelomyphora, Peniocereus, Pereskia, Pereskiopsis, Pilosocereus, Polaskia, Praecereus, Pseudoacanthocereus, Pseudorhipsalis, Pterocactus, Pygmaeocereus, Quiabentia, Rauhocereus, Rebutia, Rhipsalis, Samaipaticereus, Schlumbergera, Sclerocactus , Selenicereus, Stenocactus, Stenocereus, Stephanocereus, Stetsonia, Strombocactus, Tacinga, Thelocactus, Turbinicarpus, Uebelmannia, Weberbauerocereus, Weberocereus, Yungasocereus), Campanulaceae (in particular the species: Brighamia), Capparidaceae (in particular the species: Maerua), Caricaceae ( in particular the species: Carica, Jacarathia), Chenopodiaceae, Cochlospermaceae, Commelinaceae (in particular the species: Aneilema, Callisia, Cyanotis, Tradescantia, Tripogandra), Convolvulaceae (in particular the species: Ipomea, Sictocardia, Turbina), Crassulaceae (in particular the species: Adromischus, Aeonium, Afrovivella, Aichryson, Cotyledon, Crassula, Cremnophila, Cremnosedum, Dudleya, Echeveria, Graptopetalum, Hylotelephium ^" , Hypagophytum, Kalanchoe, Lenophyllum, Meterostachys, Monanthes, Orostachys, Pachyphytum, Perrierosedum, Phedimus, Pistorinia, Prometheum, Pseudosedum, Rhodiola, Rosularia, Sedella, Sedum, Sempervivum, Sinocrassula, Thompsonella , Tylecodon, Umbilicus, Villadia), Cucurbitaceae (in particular the species: Apodanthera, Brandegea, Cephalopentandra, Ceratosanthes, Citrullus, Coccinia, Corallocarpus, Cucumella, Cucumis, Cucurbita, Cyclantheropsis, Dendrosicyos, Doyera, Eureindra, Fevillea, Gerrandanthus, Gynostemma, Halosicyos, Ibervilla, Kedostris, Marah, Momordica, Neoalsomitra, Odosicyos, Parasicyos, Syrigia, Telfairia, Trochomeria, Trochomeriopsis, Tumamoca, Xerosicyos, Zehneria, Zygosicyos), Didiereaceae (in particular the species: Alluaudia, Alluaudiopsis, Decaria, Didieara), Dioscoreaceae (in particular the species: Dioscorea), Doryanthaceae (in particular the species: Doryanthes), Ericaceae (in particular the species: Sphyrospermum), Eriospermaceae (in particular the species: Eriospermum), Euphorbiaceae, Fabaceae (in particular the species: Delonix, Dolichos, Erythrina, Neorautanenia, Pachyrhizus, Tylosema), Fouquieriaceae (in particular species: Fouquieria), Geraniaceae (in particular species: Monsonia, Pelargonium), Gesneriaceae (in particular species es: Aeschynanthus, Alsobia, Chirita, Codonanthe, Columnea, Nematanthus, Sinningia, Streptocarpus), Hyacinthaceae (in particular: Albuca, Bowiea, Dipcadi, Drimia, Drimiopsis, Hyacinthus, Lachenalia, Ledebouria, Litanthus, Massonia, Ornithogalum, Rhadamanthus, Rhodocodon, Schizobasis, Whiteheadia), Icacinaceae (in particular the species: Pyrenacantha), Lamiaceae (in particular the species: Aeollanthus, Dauphinea, Perrierastrum, Plectranthus, Solenostemon, Tetradenia, Thorncroftia), Lentibulariaceae, Loasaceae (in particular species: Schismocarpus) , Loranthaceae (in particular species: Tapinanthus), Melastomataceae (in particular species: Medinilla), Meliaceae (in particular species: Entandrophragma), Menispermaceae (in particular species: Chasmanthera, Stephania, Tinospora), Moraceae (especially species: Dorstenia, Ficus), Moringaceae (in particular species: Moringa), Nolanaceae (in particular species: Nolana), Nolinaceae (e n particular species: Beaucarnea, Calibanus, Dasylirion, Nolina), Orchidaceae, Oxalidaceae (in particular the species: Oxalis), Passifloraceae (in particular the species: Adenia), Pedaliaceae (in particular the species: Pterodiscus, Sesamothamnus, Uncarina), Phyllanthaceae (in particular species: Phyllanthus), Phytolaccaceae (in particular species: Phytolacca), Piperaceae (in particular species: Peperomia), Portulacaceae (in particular species: Amphipetalum, Anacampseros, Avonia, Calyptrotheca, Ceraria, Cistanthe, Dendroportulaca, Grahamia, Lewisia, Parakeel, Portulaca, Portulacaria, Schreiteria, Talinella, Talinum), Rubiaceae (in particular the species: Anthorrhiza, Hyanophytum, Hydrophylax, Myrmecodia, Myrmephythum, Phylohydrax, Squamellaria) , Ruscaceae (in particular the species: Cordyline, Dracaena, Sansevieria), Sapindaceae (in particular the species: Erythrophysa), Saxifragaceae, Sterculiaceae (in particular the species: Brachychiton, Sterculia), Urticaceae (in particular the species: Laportea, Obertia, Pilea, Sarcopilea), Viscaceae (in particular the species: Viscum), Vitaceae (in particular the species: Cissus, Cyphostemma), Xahthorrhoeaceae and Zygophyllaceae.

This step 1 is carried out in a white room, under an air atmosphere, with a constant lighting of more than 100 000 liters, at a temperature of 30 ° C., and at a relative humidity of 50%. This step is performed by successively transplanting part of the plant, in particular part of the root. The illumination was of the type emitting more than 95% of the rays (in particular more than 99%) in the range 100 nm to 700 nm, preferably 400 to 520 nm.

Step 2: subculture of the dedifferentiated cells of step 1 in an in vitro culture medium for the development and elicitation of the cells.

The elicitation development of the cells of step 1 was performed in one mile in vitro under a gaseous atmosphere containing oxygen and CO 2 in a cycle comprising 100 low light periods with a brightness of less than 10 lux ( 1 to 5 lux) for 1 hour under an atmosphere consisting of humid air (75% relative humidity) enriched with CO2 (so that the CO2 content is 5%) and having a temperature of 30 ° C, these periods of development / elicitation under low (or without) brightness (advantageously substantially total darkness) being separated from each other by a period of brightness or illumination of more than 100 000 lux (The lighting was of the type emitting at more than 95% of the rays (in particular more than 99%) in the range 100 nm to 700 nm, preferably 400 to 520 nm) for 1 hour under an atmosphere consisting of humid air (75% relative humidity) enriched with CO2 (so that the CO2 content of the atmosphere is 5%) and having a temperature of 45 ° C. The transition from a dark state to an illuminated state is achieved by moving an opaque wall. This culture is operated in a white room or sterile or asceptic.

It has been noted that this method of culturing and elicating the cells makes it possible to obtain a higher content of phytoalexins, flavanoids (ratin, gallic acid, isorhamnetine derivatives, etc.) compared to that obtained by in vitro culture under a specific method. a gaseous atmosphere containing oxygen and CO 2 in a permanent lighting cycle, but even in a cycle comprising periods of low light with a brightness of less than 10 lux (from 1 to 5 lux) for 12 to 24 hours under an atmosphere consisting of humid air (relative humidity of 75%) enriched with CO2 (so that the CO 2 content is 5%) and having a temperature of 30 ° C, these periods of low (or even) brightness being separated l from each other by a period of brightness of more than 100000 lux for 12 hours under a humid air atmosphere (relative humidity of 75%) enriched with CO2 (so that the CO2 content of the atmosphere is 5%) and present both a temperature of 45 ° C.

 It has also been noted that the enrichment of the CO 2 atmosphere has a possitive effect on the formation of phytoalexins, flavanoids, etc.

Step 3: Extraction of dedifferentiated and elicited cells in culture medium in vitro, for example by filtration of the culture medium followed by one or more washing steps (with or without rinsing), in particular carried out so as not to destroy the structure cell membranes.

The dedifferentiated and eluted cells in culture medium, washed, can be directly mixed with one or more cosmetic excipients (see step 6).

For example, the fresh cells are mixed with glycerol and / or one or more glycols and / or one or more oils (advantageously of the vegetable type), the proportion by weight of the mixture in plant cells advantageously being from 1 to 20%, this mixture then constituting a product suitable for use in the preparation of a cosmetic composition.

Step 4 optional, but advantageous: Drying or lyophilization of dedifferentiated and elicited cells in culture medium in vitro, this drying operation being advantageously operated so as not to destroy the cell membrane structure.

This step is advantageously carried out at a temperature below 60 ° C, for example between -60 ° C and 50 ° C.

Step 5 possible, but advantageous: grinding. The grinding is done so that the particle size is less than 50μπι. It is advantageous to carry out the grinding operation of the dedifferentiated and elicited cells in the presence of one or more agents or excipients of the cosmetic composition so as to ensure the release of phytoalexins and other compounds from the cells in at least some agents. of the cosmetic composition.

Step 6: mixing and / or incorporation into one or more excipients and / or other active ingredients (especially other plant cells / broyais) for the preparation of the composition for topical use. For example, mixing fresh plant cells in glycerol and / or one or more glycols and / or in one or more oils to obtain a composition that is ready to be used for the preparation of a topical cosmetic composition by adding one or more additional excipients. Example of antioxidant pharmacological activity

The anti-radical activity of the cells or crushed plant cells produced by the method described above was studied in vitro, using a model of SKTNETHIC ® reconstituted epidemics, revealing this activity by malondialdehyde (MDA) assay, after induction by ultraviolet B light.

In conclusion, the cells or the ground material obtained by the process according to the invention exhibit an anti-radical effect both under physiological conditions and under conditions of induction by ultraviolet B radiation. this test that the ground material has a significant anti-radical effect.

Example of dispersion of elite cells (advantageously milled) in a cosmetic base

The plant cells prepared as described above are used for the preparation of a cosmetic composition. The cells are dispersed after lyophilization without being crushed in the following base:

 demineralised water 85, 61%

 - mineral oil 9, 00%

 cetyl alcohol 3, 00%

 ceteareth - 20 0, 75%

 plant cells (crushed or not) 0, 20%

 - perfume 0, 15%

 carbomer 0, 10%

 - methylchloroisothiazoline

 and methylisothiazoline [kathon CG] 0, 065%

- sodium hydrox of ^(45%) 0 06%

 - butylated hydroxyanisole 0.66%

TOTAL 100, 00%

The composition obtained shows a homogeneous dispersion of the cells or the crushed cell in the cream and a very fine particle size. The study of cleanliness showed the absence of germs and fungi as well as a remarkable stability of the composition. The result obtained having been tested in a transcutaneous study made it possible to see the passage of the active principles including polyphenols and other flavanoids through the cutaneous tissue.

Plant cells (crushed or not) can be used in creams, lotions, shampoos, gels, solutions, milks

The proportion of the cells or the crushed cell in the form of a viscous suspension or a gel or a substantially dry powder is a function of the nature of the composition for topical use and the desired application. It is advantageously between 0.01 and 5%, but can reach up to 25%.

Obviously, the invention is not limited to the embodiments given above and it is possible to produce the composition for topical use in other forms, such as oil, ointment, lakes, make-up (foundation, powder , lipstick, pencil, mascara, eye shadow) which also fall within the scope of the invention. Cosmetic compositions according to the invention (with a content of 1% of vegetable plant macerate - in dry form) were tested on volunteers. It has been noted that such compositions have an anti-aging effect, a protective effect on the skin, an anti-oxidant, antiradical, anti-fungal, anti-acne, skin regeneration and the like.

Claims

 claims

1. A composition for topical application, in particular a cosmetic composition, containing dedifferentiated and elicited plant cells in culture in vitro or, advantageously, a crushed material of such dedifferentiated plant cells, said mash containing at least one phytoalexin then comprising at least 95%, advantageously at least 97%, preferably at least 99% by weight of all of the dry materials from the dedifferentiated and elicited plant cells in vitro, said elite dedifferentiated plant cells or said ground material being dispersed in said composition or being in a form capable of being dispersed in said composition, characterized in that the dedifferentiated plant cells, optionally in the form of crushed material, are chosen from the group consisting of the following families: Agavaceae (in particular the species: Agave, Beschorneria, Chlorophytum, Furcraea, Hesperaloe, Hesperoyu cca, Yucca), Aizoaceae, Amaranthaceae (in particular the species: Arthraerva), Amaryllidaceae (in particular the species: Boophane, Brunsvigia, Cyrtanthus, Haemanthus, Rauhia), Anacardiaceae (in particular the species: Operculicarya, Pachycormus), Apiaceae (in particular the species: Steganotaenia), Apocynaceae (in particular the species: Adenium, Mandevilla, Pachypodium, Plumeria), Araceae (in particular the species: Zamioculcas zamiifolia); Araliaceae (in particular the species: Cussonia), Asclepiadaceae (in particular the species: Absolmsia, Asclepias, Aspidoglossum, Aspidonepsis, Baynesia, Brachystelma, Caralluma, Ceropegia, Cibirhiza, Cynanchum, Dischidia, Dischidiopsis, Duvalia, Duvaliandra, Echidnopsis, Edithcolea, Fanninia , Fockea, Glossostelma, Hoodia, Hoya, Huernia, Huerniopsis, Ischnolepis, Larryleachia, Lavrania, Madangia, Marsdenia, Matelea, Micholitzia, Miraglossum, Notechidnopsis, Odontostelma, Ophionella, Orbea, Orbeanthus, Pachycarpus, Pectinaria, Petopentia, Piaranthus, Pseudolithos, Quaqua , Raphionacme, Rhytidocaulon, Riocreuxia, Sarcorrhiza, Sarcostemma, Schizoglossum, Schlechterella, Stapelia, Stapelianthus, Stapeliopsis, Stathmostelma, Stenostelma, Stomatostemma, Tavaresia, Trachycalymma, Tridentea, Tromotriche, White-sloanea, Xysmalobium), Asparagaceae (in particular the species: Myrsiphyllum), Asphodelaceae ((in particular the species: Aloe, Astroloba, Bulbine, Chortolirion, Gasteria, Haworthia, Poellnitzia, Trachyandra), Asteraceae (in particular species: Baeriopsis, Coulterella, Crassocephalum, Didelta, Gynura, Osteospermum, Othonna, Polyachyrus, Pteronia, Senecio), Balsaminaceae (in particular the species: Impatiens), Basellaceae (in particular the species: Anredera, Basella), Begoniaceae (in particular species: Begonia), Bombacaceae (in particular the species: Adansonia, Cavanillesia, Ceiba, Pseudobombax), Brassicaceae (in particular the species: Heliophila, Lepidium), Bromeliaceae, Burseraceae (in particular the species: Beiselia, Bursea, Commiphora), Cactaceae (in particular the species: Acanthocalycium, Acanthocereus, Ariocarpus, Armatocereus, Arrojadoa, Arthrocereus, Astrophytum, Austrocactus, Aztekium, Bergerocactus, Blossfeld Brachycereus, Browningia, Brasilicereus, Calymmanthium, Carnegiea, Cephalocereus, Cephalocleistocactus, Cereus, Cintia, Cipocereus, Cleistocactus, Coleocephalocereus, Copiapoa, Corryocactus, Coryphantha, Dendrocereus, Denmoza, Discocactus, Disocactus, Echinocactus, Echinocereus, Echinopsis, Epiphyllum, Epithelantha, Eriosyce, Escobaria, Escontria, Espostoa, Espbstoopsis, Eulychnia, Facheiroa, Ferocactus, Frailea, Geohintonia, Gymnocalycium, Haageocereus, Harrisia, Hatiora, Hylocereus, Jasminocereus, Lasiocereus, Leocereus, Lepismium, Leptocereus, Leuchtenbergia, Lophophora, Maihuenia, Malacocarpus, Mammillaria, Mammilloydia, Matucana, Melocactus, Micranthocereus, Mila, Monvillea, Myrtillocactus, Neobuxbaumia, Neolloydia, Neoraimondia, Neowerdermannia, Obregonia, Opuntia, Oreocereus, Oroya, Ortegocactus, Pachycereus, Parodia, Pediocactus, Pelomyphora, Peniocereus, Pereskia, Pereskiopsis, Pilosocereus, Polaskia, Praecereus, Pseudoacanthocereus, Pseudorhipsalis, Pterocactus, Pygmaeoce Reusal, Quiabentia, Rauhocereus, Rebutia, Rhipsalis, Samaipaticereus, Schlumbergera, Sclerocactus, Selenicereus, Stenocactus, Stenocereus, Stephanocereus, Stetsonia, Strombocactus, Tacinga, Thelocactus, Turbinicarpus, Uebelmannia, Weberbauerocereus, Weberocereus, Yungasocereus), Campanulaceae (in particular species: Brighamia), Capparidaceae (in particular the species: Maerua), Caricaceae (in particular the species: Carica, Jacarathia), Chenopodiaceae, Cochlospermaceae, Commelinaceae (in particular the species: Aneilema, Callisia, Cyanotis, Tradescantia, Tripogandra), Convolvulaceae (in particular the species: Ipomea, Sictocardia, Turbina) , Crassulaceae (in particular the species: Adromischus, Aeonium, Afrovivella, Aichryson, Cotyledon, Crassula, Cremnophila, Cremnosedum, Dudleya, Echeveria, Graptopetalum, Hylotelephium, Hypagophytum, Kalanchoe, Lenophyllum, Meterostachys, Monanthes, Orostachys, Pachyphytum, Perrierosedum, Phedimus, Pistorinia, Prometheum, Pseudosedum, Rhodiola, Rosularia, Sedella, Sedum, Sempervivum, Sinocrassula, Thompsonella, Tylecodon, Umbilicus, Villadia), Cucurbitaceae (in particular the species: Apodanthera, Brandegea, Cephalopentandra, Ceratosanthes, Citrullus, Coccinia, Corallocarpus, Cucumella, Cucumis, Cucurbita, Cyclantheropsis, Dendrosicyos, Doyera, Eureindra, Fevillea, Gerrandanthus, Gynostemma, Halosicyos , Ibervilla, Kedostris, Marah, Momordica, Neoalsomitra, Odosicyos, Parasicyos, Syrigia, Telfairia, Trochomeria, Trochomeriopsis, Tumamoca, Xerosicyos, Zehneria, Zygosicyos), Didiereaceae (especially the species: Alluaudia, Alluaudiopsis, Decaria, Didieara), Dioscoreaceae ( in particular the species: Dioscorea), Doryanthaceae (in particular the species: Doryanthes), Ericaceae (in particular the species: Sphyrospermum), Eriospermaceae (in particular the species: Eriospermum), Euphorbiaceae, Fabaceae (in particular the species: Delonix, Dolichos , Erythrina, Neorautanenia, Pachyrhizus, Tylosema), Fouquieriaceae (in particular the species: Fouquieria), Geraniaceae (in particular the species: Monsonia, Pelargonium), Gesneriaceae (in particular the species: Aeschynanthus, Alsobia, Chirita, Codonanthe, Columnea, Nematanthus , Sinningia, Streptocarpus), Hyacinthaceae (in particular the species: Albuca, Bowiea, Dipcadi, Drimia, Drimiopsis, Hyacinthus, Lachenalia, Ledebouria , Litanthus, Massonia, Ornithogalum, Rhadamanthus, Rhodocodon, Schizobasis, Whiteheadia), Icacinaceae (in particular the species: Pyrenacantha), Lamiaceae (in particular the species: Aeollanthus, Dauphinea, Perrierastrum, Plectranthus, Solenostemon, Tetradenia, Thorncroftia), Lentibulariaceae, Loasaceae (in particular species: Schismocarpus), Loranthaceae (in species: Tapinanthus), Melastomataceae (in particular species: Medinilla), Meliaceae (in particular species: Entandrophragma), Menispermaceae (in particular species: Chasmanthera, Stephania, Tinospora), Moraceae (in particular species: Dorstenia, Ficus), Moringaceae (in particular the species: Moringa), Nolanaceae (in particular the species: Nolana), Nolinaceae (in particular the species: Beaucarnea, Calibanus, Dasylirion, Nolina), Orchidaceae, Oxalidaceae (in particular the species: Oxalis) , Passifioraceae (in particular the species: Adenia), Pedaliaceae (in particular the species: Pterodiscus, Sesamothamnus, Uncarina), Phyllanthaceae (in particular the species: Phyllanthus), Phytolaccaceae (in particular the species: Phytolacca), Piperaceae (in particular the species: Peperomia), Portulacaceae (in particular the species: Amphipetalum, Anacampseros, Avonia, Calyptrotheca, Ceraria, Cistanthe, Dendroportulaca, Grahamia, Lewisia, Parakeel Portulaca, Portulacaria, Schreiteria, Talinella, Talinum), Rubiaceae (in particular the species: Anthorrhiza, Hydnophytum, Hydrophylax, Myrmecodia, Myrmephythum, Phylohydrax, Squamellaria), Ruscaceae (in particular the species: Cordyline, Dracaena, Sansevieria), Sapindaceae (in particular the species: Erythrophysa), Saxifragaceae, Sterculiaceae (in particular the species: Brachychiton, Sterculia), Urticaceae (in particular the species: Laportea, Obertia, Pilea, Sarcopilea), Viscaceae (in particular the species: Viscum), Vitaceae (in particular species: Cissus, Cyphostemma), Xanthorrhoeaceae and Zygophyllaceae, which were eluted in vitro in a gaseous atmosphere containing oxygen and CO 2 at a temperature between 15 ° C and 50 ° C in a cycle including periods of dark or low light with a brightness of less than 10 lux for 10 minutes to 12 hours, preferably for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of dark or low light separated from each other by a period of brightness in the range of 100 to 700 nm, preferably from 400 to 520 nm, of more than 100 lux for 30 minutes. minutes to 24 hours, advantageously 1 hour to 12 hours, preferably 1 to 6 hours, optionally followed by a grinding step to form a dedifferentiated plant cell broth. Composition according to Claim 1, characterized in that the plant cells have been eluted in vitro in a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C and 50 ° C in a cycle comprising at least four, in particular at least six, preferably at least ten periods of darkness or low light with a brightness of less than 10 lux for 10 minutes to 12 hours, advantageously for 15 minutes and 0 hours, preferably between 20 minutes and 3 hours, periods of darkness, separated from each other by a period of brightness in the range of 100 to 700 nm, preferably from 400 to 520 nm, of more than 100 lux for 30 minutes to 24 hours, advantageously 1 hour to 12 hours. hours, preferably from 1 to 6 hours, optionally followed by a grinding step to form a grind.

 Composition according to Claim 1 or 2, characterized in that the plant cells have been eluted in vitro in an atmosphere containing a degree of humidity of more than 50%.

 Composition according to any one of the preceding claims, characterized in that the plant cells are dedifferentiated and elicited in an in vitro culture medium under a gaseous atmosphere containing oxygen and CO 2 at a temperature of between 15 ° C. and 50 ° C. ° C according to a cycle comprising periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, preferably for 15 minutes and hours, preferably between 20 minutes and 3 hours, periods of darkness or low light separated l from one another by a brightness period in the range of 100 to 700 nm, preferably 400 to 520 nm, more than 100 lux, preferably more than 1000 percent, for 30 minutes to 24 hours, preferably 1 hour to 12 hours. hours, preferably from 1 to 6 hours, optionally followed by a grinding step to form a grind.

Composition according to any one of the preceding claims, characterized in that the plant cells are at least partially elicited by brightness periods in the range of 100 to 700 nm, preferably 400 to 520 nm, of more than 50000 lux, in particular more than 100000 lux.

6. Composition according to any one of the preceding claims, characterized in that the plant cells are dedifferentiated and elicited in an in vitro medium in an atmosphere containing oxygen and at least 1% of CO2 by volume.

7. Composition according to any one of the preceding claims, characterized in that the plant cells are dedifferentiated and elicited in an in vitro medium under a gaseous atmosphere containing oxygen and at least 1% by volume of CO2, and a relative humidity. at least 50% according to a cycle comprising periods of dark or low light with a brightness of less than 10 lux at a temperature between 15 ° C and 30 ° C for 10 minutes to 12 hours, preferably for 15 minutes and hours, preferably between 20 minutes and 3 hours, periods of darkness separated from each other by a period of brightness in the range of 100 to 700 nm, preferably from 400 to 520 nm, of more than 1000 lux, advantageously more than 100OOlux, preferably more than 500001ux, for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours, optionally followed by a milling step to to form a grind.

 8. A composition according to any one of claims 1 to 7, characterized in that the ground material is a crushed dedifferentiated and eluted cells in vitro, said cells being at least partially dried, preferably lyophilized, before grinding.

9. Composition according to any one of claims 1 to 8, characterized in that it contains from 0.005 to 25% by weight, preferably from 0.005 to 5% by weight of plant cells dedifferentiated and elicited in vitro, or ground material. such cells, this weight being calculated in dry form.

10. Composition according to one of claims 1 to 9, characterized in that the ground material has an average particle size of solid particles less than 100 μπι, preferably less than 10 μηι, preferably less than 1 μιη.

11. Composition according to any one of the preceding claims, characterized in that the dedifferentiated and elicited plant cells in vitro or the crushed of such cells are in the form of a viscous suspension or a gel or a powder. substantially dry, said suspension, gel or powder being advantageously in a form capable of being dispersed in the composition.

12. Composition according to one of the preceding claims, as an antioxidant, anti-radical, anti-inflammatory, anti-proliferative, relaxing, vascular and / or anti-aging composition, said composition comprising an effective amount of vegetable plant meal such as described in any one of the preceding claims.

13. Process for the preparation of a composition for topical use according to any one of the preceding claims, characterized in that dedifferentiated plant cells of a species chosen from the group consisting of the following families of the following families: Agavaceae ( in particular the species: Agave, Beschorneria, Chlorophytum, Furcraea, Hesperaloe, Hesperoyucca, Yucca), Aizoaceae, Amaranthaceae (in particular the species: Arthraerva), Amaryllidaceae (in particular the species: Boophane, Brunsvigia, Cyrtanthus, Haeman hus, Rauhia), Anacardiaceae (in particular the species: Operculicarya, Pachycormus), Apiaceae (in particular the species: Steganotaenia), Apocynaceae (in particular the species: Adenium, Mandevilla, Pachypodium, Plumeria), Araceae (in particular species : Zamioculcas zamiifolia); Araliaceae (in particular the species: Cussonia), Asclepiadaceae (in particular the species: Absolmsia, Asclepias, Aspidoglossum, Aspidonepsis, Baynesia, Brachystelma, Caralluma, Ceropegia, Cibirhiza, Cynanchum, Dischidia, Dischidiopsis, Duvalia, Duvaliandra, Echidnopsis, Edithcolea, Fanninia , Fockea, Glossostelma, Hoodia, Hoya, Huernia, Huerniopsis, Ischnolepis, Larryleachia, Lavrania, Madangia, Marsdenia, Matelea, Micholitzia, Miraglossum, Notechidnopsis, Odontostelma, Ophionella, Orbea, Orbeanthus, Pachycarpus, Pectinaria, Petopentia, Piaranthus, Pseudolithos, Qtiaqua, Raphionacme, Rhytidocaulon, Riocreuxia, Sarcorrhiza, Sarcostemma, Schizoglossum, Schlechterella, Stapelia, Stapelianthus, Stapeliopsis, Stathmostelma, Stenostelma, Stomatostemma, Tavaresia, Trachycalymma, Tridentea, Tromotriche, White-sloanea, Xysmalobium), Asparagaceae (especially species: Myrsiphyllum), Asphodelaceae ((in particular species: Aloe, Astroloba, Bulbine, Chortolirion, Gasteria, Haworthia , Poellnitzia, Trachyandra), Asteraceae (in particular the species: Baeriopsis, Coulterella, Crassocephalum, Didelta, Gynura, Osteospermum, Othonna, Polyachyrus, Pteronia, Senecio), Balsaminaceae (in particular species: Impatiens), Basellaceae (in particular species : Anredera, Basella), Begoniaceae (in particular the species: Begonia), Bombacaceae (in particular the species: Adansonia, Cavanillesia, Ceiba, Pseudobombax), Brassicaceae (in particular the species: Heliophila, Lepidium), Bromeliaceae, Burseraceae (in particular species: Beiselia, Bursea, Commiphora), Cactaceae (in particular the species: Acanthocalycium, Acanthocereus, Ariocarpus, Armatocereus, Arrojadoa, Arthro Cereus, Astrophytum, Austrocactus, Aztekium, Bergerocactus, Blossfeldia, Brachycereus, Browningia,. Brasilicereus, Calymmanthium, Carnegiea, Cephalocereus, Cephalocleistocactus, Cereus, Cintia, Cipocereus, Cleistocactus, Coleocephalocereus, Copiapoa, Corryocactus, Coryphantha, Dendrocereus, Denmoza, Discocactus, Disocactus, Echinocactus, Echinocereus, Echinopsis, Epiphyllum, Epithelantha, Eriosyce, Escobaria, Escontria, Espostoa, Espostoopsis, Eulychnia, Facheiroa, Ferocactus, Frailea, Geohintonia, Gymnocalycium, Haageocereus, Harrisia, Hatiora, Hylocereus, Jasminocereus, Lasiocereus, Leocereus, Lepismium, Leptocereus, Leuchtenbergia, Lophophora, Maihuenia, Malacocarpus, Marnmillaria, Mammilloydia, Matucana, Melocactus, Micranthocereus, Mila, Monvillea, Myrtillocactus, Neobuxbaumia, Neolloydia, Neoraimondia, Neowerdermannia, Obregonia, Opuntia, Oreocereus, Oroya, Ortegocactus, Pachycereus, Parodia, Pediocactus, Pelomyphora, Peniocereus, Pereskia, Pereskiopsis, Pilosocereus, Polaskia, Praecereus, Pseudoacanthocereus, Pseudorhipsalis, Pterocacrus, Pygmaeocereus, Quiabentia, Rauhocereus , Rebutia, Rhipsalis,. Samaipaticereus, Schlumbergera, Sclerocactus, Selenicereus, Stenocactus, Stenocereus, Stephanocereus, Stetsonia, Strombocactus, Tacinga, Thelocactus, Turbinicarpus, Uebelmannia, Weberbauerocereus, Weberocereus, Yungasocereus), Campanulaceae (in particular the species: Brighamia), Capparidaceae (in particular the species: Maerua), Caricaceae (in particular the species: Carica, Jacarathia), Chenopodiaceae, Cochlospermaceae, Commelinaceae (in particular the species: Aneilema, Callisia, Cyanotis, Tradescantia, Tripogandra), Convolvulaceae (in particular species : Ipomea, Sictocardia, Turbina), Crassulaceae (in particular the species: Adromischus, Aeonium, Afrovivella, Aichryson, Cotyledon, Crassula, Cremnophila, Cremnosedum, Dudleya, Echeveria, Graptopetalum, Hylotelephium, Hypagophytum, Kalanchoe, Lenophyllum, Meterostachys, Monanthes, Orostachys , Pachyphytum, Perrierosedum, Phedimus, Pistorinia, Prometheum, Pseudosedum, Rhodiola, Rosularia, Sedella, Sedum, Sempervivum, Sinocrassula, Thompsonella, Tylecodon, Umbilicus, Villadia), Cucurbitaceae (especially the species: Apodanthera, Brandegea, Cephalopentandra, Ceratosanthes, Citrullus , Coccinia, Corallocarpus, Cucumella, Cucumis, Cucurbita, Cyclantheropsis, Dendrosicyos, Doyera, Euremdra, Fevi llea, Gerrandanthus, Gynostemma, Halosicyos, Ibervilla, Kedostris, Marah, Momordica, Neoalsomitra, Odosicyos, Parasicyos, Syrigia, Telfairia, Trochomeria, Trochomeriopsis, Tumamoca, Xerosicyos, Zehneria, Zygosicyos), Didiereaceae (in particular the species: Alluaudia, Alluaudiopsis, Decaria, Didieara), Dioscoreaceae (in particular the species: Dioscorea), Doryanthaceae (in particular the species: Doryanthes), Ericaceae (in particular the species: Sphyrospermum), Eriospermaceae (in particular the species: Eriospermum), Euphorbiaceae, Fabaceae (in particular particular species: Delonix, Dolichos, Erythrina, Neorautanenia, Pachyrhizus, Tylosema), Fouquieriaceae (in particular the species: Fouquieria), Geraniaceae (in particular the species: Monsonia, Pelargonium), Gesneriaceae (in particular the species: Aeschynanthus, Alsobia, Chirita, Codonanthe, Columnea, Nematanthus, Sinriingia, Streptocarpus), Hyacinthaceae (especially species: Albuca, Bowiea, Dipcadi, Drimia, Dr moss, Hyacinthus, Lachenalia, Ledebouria, Litanthus, Massonia, Ornithogalum, Rhadamanthus, Rhodocodon, Schizobasis, Whiteheadia), Icacinaceae (in particular the species: Pyrenacantha), Lamiaceae (in particular the species: Aeollanthus, Dauphinea, Perrierastrum, Plectranthus, Solenostemon, Tetradenia, Thorncroftia), Lentibulariaceae, Loasaceae (in particular species: Schismocarpus), Loranthaceae (in particular species: Tapinanthus), Melastomataceae (in particular species: Medinilla), Meliaceae (in particular species: Entandrophragma), Menispermaceae (in particular species: Chasmanthera, Stephania, Tinospora), Moraceae (in particular species: Dorstenia, Ficus), Moringaceae (in particular species: Moringa), Nolanaceae (in particular species: Nolana), Nolinaceae (in particular species: Beaucarnea, Calibanus, Dasylirion, Nolina), Orcbidaceae, Oxalidaceae (in particular species: Oxalis), Passifloraceae (in particular species Adenia), Pedaliaceae (in particular species: Pterodiscus, Sesamothamnus, Uncarina), Phyllanthaceae (in particular species: Phyllanthus), Phytolaccaceae (in particular species: Phytolacca), Piperaceae (in particular species: Peperomia), Portulacaceae ( in particular the species: Amphipetalum, Anacampseros, Avonia, Calyptrotheca, Ceraria, Cistanthe, Dendroportulaca, Grahamia, Lewisia, Parakeelya, Portulaca, Portulacaria, Schreiteri a, Talinella, Talinum), Rubiaceae (in particular the species: Anthorrhiza, Hydnophytum, Hydrophylax, Myrmecodia, Myrmephythum, Phylohydrax, Squamellaria), Ruscaceae (in particular the species: Cordyline, Dracaena, Sansevieria), Sapindaceae (in particular the species: Erythrophysa), Saxifragaceae, Sterculiaceae (in particular the species: Brachychiton, Sterculia), Urticaceae (in particular the species: Laportea, Obertia, Pilea, Sarcopilea), Viscaceae (in particular the species: Viscum), Vitaceae (in particular the species: Cissus, Cyphostemma), Xanthorrhoeaceae and Zygophyllaceae, in an in vitro culture medium so as to allow growth of the cells, while eliciting them, said growth and elicitation being carried out in an in vitro medium under a gaseous atmosphere containing oxygen and C02 at a temperature between 15 ° C and 50 ° C according to a cycle comprising periods of dark or low light with a brightness of less than 1 0 lux for 10 minutes to 12 hours, advantageously for 15 minutes and hours, preferably between 20 minutes and 3 hours, periods of dark or low light separated from each other by a period of brightness in the range of 100 to 700 nm, preferably 400 to 520 nm, more than 100 lux, advantageously more than 1000, preferably more than 10000, for 30 minutes to 24 hours, preferably 1 hour to 12 hours, preferably 1 to 6 hours, that one cultivates and elects said cells differentiated plants in their culture medium for a cycle sufficiently long in time for the synthesis of a sufficient amount of metabolites in the dedifferentiated cells, in that optionally, but advantageously, at least partially the cells are separated from the culture medium, and in that the elite plant cells of the culture medium are mixed with one or more acceptable excipients for topical application to prepare a topical, advantageously cosmetic composition according to any one of claims 1 to 12, the elite plant cells optionally being but advantageously, crushed before and / or after mixing with one or more excipients.

14. A process according to claim 13, characterized in that said elite cells in vitro are subjected to drying, advantageously to lyophilization, optionally followed by grinding, before mixing the cells or the crushed cell with one or more acceptable excipients for topical application.

15. A method according to claim 13 or 14, wherein differentiated plant cells are cultured in vitro, elicited in the in vitro culture medium, dried, and optionally ground, optionally after one or more washing and / or rinsing steps. and / or drying, and dispersed in a treatment composition of the human body.

16. A method according to any one of claims 13 to 15, characterized in that the plant cells have been eluted in vitro in a gaseous atmosphere containing oxygen and CO 2 at a temperature between 15 ° C and 50 ° C. ° C according to a cycle comprising at least four, in particular at least six, preferably at least ten periods of dark or low light with a brightness of less than 10 lux for 10 minutes to 12 hours, preferably for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of dark or low light separated from each other by a period of brightness in the range of 100 to 700 nm, preferably 400 to 520 nm, of more than 100 lux, advantageously more than 1000, preferably more than 10000, for 30 minutes to 24 hours, advantageously 1 hour to 12 hours, preferably 1 to 6 hours, before being optionally milled.

 17. A method according to any one of claims 13 to 16, characterized in that the plant cells have been eluted in vitro in an atmosphere containing a degree of relative humidity of more than 50%.

 18. A method according to any one of claims 13 to 17, characterized in that the plant cells are dedifferentiated and elicited in an in vitro culture medium under a gaseous atmosphere containing oxygen and CO 2 at a temperature between ° C and 50 ° C according to a cycle comprising periods of low light with a brightness of less than 10 lux for 10 minutes to 12 hours, preferably for 15 minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness or low luminosity separated from each other by a period of brightness in the range of 100 to 700 nm, preferably from 400 to 520 nm, of more than 100 lux, advantageously more than 100 000, preferably more than 100 000, for 30 minutes at 24 hours, advantageously 1 hour to 12 hours, preferably 1 to 6 hours, before being optionally crushed.

 19. A method according to any one of claims 13 to 18, characterized in that the plant cells are at least partially elicited by brightness periods in the range of 100 to 700 nm, preferably 400 to 520 nm, of more than 50,000. lux, in particular of more than 100000 lux.

 20. Process according to any one of claims 13 to 19, characterized in that the plant cells are dedifferentiated and elicited in an in vitro medium in an atmosphere containing oxygen and at least 1% of CO2 by volume.

21. A process according to any one of claims 13 to 20, characterized in that the plant cells are dedifferentiated and elicited in vitro in a gaseous atmosphere containing oxygen and at least 1% by volume of CO2, and at least 50% relative humidity according to a cycle comprising periods of dark or low light with a brightness of less than 10 lux at a temperature of between 15 ° C and 30 ° C for 10 minutes to 12 hours, advantageously during 15minutes and 6 hours, preferably between 20 minutes and 3 hours, periods of darkness or low light separated each other by a period of brightness in the range of 100 to 700 nm, preferably 400 to 520 nm, more than 1000 lux, preferably more than 10000 lux, preferably more than 500001ux for 30 minutes to 24 hours, advantageously 1 hour to 12 hours, preferably 1 to 6 hours at a temperature of more than 30 ° C, before being optionally crushed.

 22. Method according to any one of claims 13 to 21, characterized in that the grinding of the cells is operated to obtain a crushed cell with an average particle size of solid particles less than 100 μιη, preferably less than 10 μπι, preferably less than 1 μπι.